KR102620236B1 - Coolant preheating device of engine generator - Google Patents

Abstract

The present invention provides an automobile coolant preheating device having a power unit that generates rotational force, a coolant preheating unit that is connected to the power unit to preheat the coolant, and a case that includes a vibration reduction module and a dust removal module to protect them. .

Description

Automotive coolant preheating device {Coolant preheating device of engine generator}

The present invention relates to an automobile coolant preheating device, and more specifically, to a power unit that generates rotational force, a coolant preheater unit that is connected to the power unit to preheat the coolant, and a vibration reduction module and a dust removal module to protect them. It relates to an automobile coolant preheating device equipped with a case.

Due to the increase in electricity consumption along with various construction and construction sites, power outages from existing electricity supply companies, natural disasters, and other various problems, the consumption and demand for reserve power is rapidly increasing, and the reserve power is used to prevent various damages. As the demand for secondary power generation equipment, such as emergency power equipment at construction and construction sites, various buildings and facilities, and marine power generation equipment, increases significantly, its marketability will increase significantly.

The current preheating device has a heater that simply preheats the coolant inside the preheating block and a coolant inflow IN line, and there is only a check valve on the OUT line, so it cannot ensure smooth circulation of the coolant through natural circulation by convection heat transfer, and also inside the preheating block. Even if air enters the system, it becomes a serious cause of disrupting the natural circulation of coolant as described above. And over time, foreign matter sticks to the check valve, preventing it from functioning and becoming a major cause of obstructing the circulation of coolant.

Due to these various problems, frequent failure of the preheating heater and poor circulation of the preheated coolant not only reduces the efficiency at start-up of the power generation unit of the power unit, but also emits a lot of smoke due to incomplete combustion during initial start-up in a non-preheated state. As a result, it is becoming a major cause of environmental pollution.

In addition, vibration and noise are frequently generated due to the complex operation of the power unit, power generation unit, preheater, and power transmission unit, posing a risk to the safety of workers.

Accordingly, the present invention seeks to solve the smoke, vibration, and noise generated during the operation of the above components.

The present invention was created to solve the above problems, and the object of the present invention is to provide an automobile coolant preheating device equipped with a power unit that generates rotational force, a coolant preheater that preheats the coolant, a power generation unit, and a power transmission unit. It is done.

Another object of the present invention is to provide an automobile coolant preheating device equipped with a case in which a power unit, a coolant preheater, a power generation unit, and a power transmission unit are mounted therein.

Another object of the present invention is to provide an automobile coolant preheating device equipped with a vibration reduction module installed on the inner circumference of the case.

Another object of the present invention is to provide an automobile coolant preheating device equipped with a dust removal module installed inside the case.

The object of the present invention is not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

An automobile coolant preheating device according to an embodiment of the present invention to solve the above problem may include a power unit that generates rotational force.

In one embodiment, a coolant preheating unit connected to the power unit to increase lubricity of the power unit by preheating the coolant when the power unit stops operating, a power generation unit that generates and supplies power by the power unit, and the power unit; It may include a power transmission unit that electrically connects the power generation units to drive the power unit, converting the power in the power generation unit into power for generating power, and transmitting the power.

In one embodiment, the power unit, the coolant preheating unit, the power generation unit, and the power transmission unit are installed and protected inside, and the case is provided with a cover so that the top can be opened, and is installed along the circumference of the inside of the case. A vibration reduction module is installed inside the bottom of the case to prevent vibration and noise generated during operation of the power unit from being emitted to the outside, and is installed inside the case to prevent dust flowing into the case or harmful gases generated during operation of the power unit and the It may include a dust removal module that radiates heat from the power unit and the coolant preheating unit to the outside.

In one embodiment, the vibration reduction module includes a plurality of machining springs installed at each corner inside the case to support the vibration reduction module, and a plurality of machining springs installed at each side inside the case and supported by the plurality of machining springs. A module housing, a plurality of fixing parts formed at regular intervals on one inner side and the other side of each of the plurality of module housings, a plurality of support plates formed along the longitudinal direction of the module housing on one side of the plurality of fixing parts, a plurality of support plates, A plurality of support parts are installed at regular intervals to support between the support plates, a plurality of fixing plates are installed on one support plate among the plurality of support plates, and each of the plurality of fixing plates is spaced at a predetermined distance in one direction. A plurality of reduction units are formed to attenuate the impact transmitted to the case, and a reduction unit fixing member installed on one side of the corresponding support plate so as to be fastened to and fixed to at least one of the plurality of reduction units. can do.

In one embodiment, the reduction unit includes a reduction unit body provided in a cylindrical shape and a thread (E) formed at the rear end, a fitting member fastened along the screw thread (E) of the reduction unit body and an insertion member formed at the center ( 272), a sensor bracket installed at the front end of the reduction unit body, a vibration sensor for measuring vibration caused by an external impact is built in, and a plurality of sensor fixing rings are provided for fixing the vibration sensor, and the sensor bracket A sensor protection member is fixed by and is formed to protrude from the front end of the reduction unit body, a vibration measuring unit installed on one side of the reduction unit body to calculate and display the average value of the vibration measured by the vibration sensor, and the fitting. A vibration spring is inserted into the insertion member of the member 272 to reduce external shock, is built into the reduction part body, and an insertion protrusion is formed at the rear end to be inserted into the front end of the vibration spring, and is used to reduce vibration. It may include a buffer unit with a built-in spring, a fastening screw at the upper end of the buffer unit, a buffer spring inserted into the fastening screw, and a fastening unit fastened in that order with a separation prevention ring for preventing separation of the buffer unit from the reduction unit body.

In one embodiment, the vibration reduction module is supported inside the case by the machining spring, and when an external shock is transmitted to the case, the vibration reduction module reduces the external shock in the vibration spring and the buffer unit among the reduction units, and reduces the external shock in the vibration spring and the buffer unit among the reduction units. It may further include a feature of measuring shock at the vibration sensor, calculating an average value of vibration, and displaying the average value of the vibration on the vibration measuring unit.

In one embodiment, the dust removal module includes an air tank installed inside the case to store compressed air and supplying compressed air with a built-in pump operated under the control of an electrically connected control unit, and a constant constant pressure on the bottom of the case. A plurality of devices may be inserted at intervals apart from each other, and may include a spray portion that sprays compressed air into the case, and a pipe that is integrally connected to each of the several spray portions and moves the compressed air sprayed from the air tank.

In one embodiment, the injection unit is a pipe protection member that embeds the pipe and has a plurality of injection grooves in the center through which compressed air supplied from the pipe is sprayed and a plurality of bolt holes D into which bolts can be inserted along the circumference. A fitting member 3221 is protrudingly formed on one side to be fastened to the injection groove of the pipe protection member, and a screw injection portion that supplies compressed air sprayed from the injection groove by adding rotational force, and a central portion is protruded to allow the screw injection portion to be inserted. A body fixing member is formed, a plurality of fitting grooves and bolt holes (C) are formed along the inner circumference at regular intervals to form a spray part fastening part, the spray part fastening part is fastened with the plurality of fitting grooves and is attached to the body fixing member. A spray unit fixing member is provided with a hole in the center for insertion, a plurality of bolt holes (B) are formed at regular intervals along the periphery, and a berm with a plurality of bolt holes (A) formed on the upper surface to be bolted to the case is formed to protrude. It can be included.

In one embodiment, the screw injection unit includes a cylindrical nozzle body, a screw body that is electrically connected to the control unit and built into the nozzle body for rotational operation, and has a screw fastening portion formed along the circumference, and one end of the screw body. It may include an auxiliary injection unit that is integrally connected to and selectively sprays compressed air under the control of the control unit.

In one embodiment, the auxiliary injection unit includes a connection portion integrally connected to one end of the screw body, an auxiliary injection nozzle integrally connected with the connection portion to selectively spray compressed air, and the screw fastening portion is connected to the screw body. A dust removal unit that removes dust flowing into the spray unit is fastened, and the dust removal module is configured to allow compressed air supplied from the air tank under the control of the control unit to pass through the plurality of spray units through the plurality of pipes. It is injected into the case, and the screw body rotates under the control of the control unit to remove dust introduced into the screw injection unit to the dust removal unit, and the compressed air supplied through the pipe due to rotation adds rotational force. Rotational injection may be performed, and the auxiliary injection nozzle of the auxiliary injection unit may be opened under control of the controller to spray compressed air.

According to the present invention, an automobile coolant preheating device is provided, which includes a power unit that generates rotational force, a coolant preheater that is connected to the power unit and preheats the coolant, and a case that includes a vibration reduction module and a dust removal module to protect them. do. The effects according to the present invention are not limited to the details exemplified above, and further various effects are included within the present invention.

Figure 1 is a side view showing the overall configuration of an automobile coolant preheating device according to the present invention.
Figure 2 shows the overall configuration of the vibration reduction module in a plan view of the case of the automobile coolant preheating device according to the present invention.
Figure 3 shows an assembly diagram of the reduction part of the automobile coolant preheating device according to the present invention.
Figure 4 shows examples of the reduction unit of the automobile coolant preheating device according to the present invention.
Figure 5 shows an embodiment of the dust removal module of the automobile coolant preheating device according to the present invention.
Figure 6 shows the overall configuration of the injection unit of the automobile coolant preheating device according to the present invention.
Figure 7 shows the overall configuration of the screw injection unit of the automobile coolant preheating device according to the present invention.
Figure 8 shows an assembly diagram of the injection unit of the automobile coolant preheating device according to the present invention.
Figure 9 shows a relationship diagram of the control unit of the automobile coolant preheating device according to the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the attached drawings. The embodiments described herein may be modified in various ways. Specific embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the attached drawings are only intended to facilitate understanding of the various embodiments. Therefore, the technical idea is not limited to the specific embodiments disclosed in the attached drawings, and it should be understood that all equivalents or substitutes included in the spirit and technical scope of the invention are included.

Terms containing ordinal numbers, such as first, second, etc., may be used to describe various components, but these components are not limited by the above-mentioned terms. The above-mentioned terms are used only for the purpose of distinguishing one component from another.

In this specification, terms such as “comprise” or “have” are intended to indicate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but are not intended to indicate the presence of one or more other features. It should be understood that this does not exclude in advance the possibility of the existence or addition of elements, numbers, steps, operations, components, parts, or combinations thereof. When a component is said to be "connected" or "connected" to another component, it is understood that it may be directly connected to or connected to the other component, but that other components may exist in between. It should be. On the other hand, when it is mentioned that a component is “directly connected” or “directly connected” to another component, it should be understood that there are no other components in between.

Meanwhile, a “module” or “unit” for a component used in this specification performs at least one function or operation. And the “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. Additionally, a plurality of “modules” or a plurality of “units” excluding a “module” or “unit” that must be performed on specific hardware or performed on at least one processor may be integrated into at least one module. Singular expressions include plural expressions unless the context clearly dictates otherwise.

In addition, when describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof is abbreviated or omitted.

Figure 1 is a side view showing the overall configuration of the coolant preheating device of the power generation unit 30 according to the present invention.

The coolant preheating device of the power generation unit 30 may include a power unit 10, a coolant preheating unit 20, a power generation unit 30, and a power conversion unit 40.

The power unit 10 operates while fuel is supplied to generate rotational force, and the rotational force is transmitted to the power generation unit 30 through a power conversion unit 40 to be described later, so that the power generation unit 30 is the power unit 10. It is equipped to generate power with the rotational force transmitted from.

The coolant preheating unit 20 may be connected to the power unit 10 and may be provided to increase lubricity of the power unit by preheating the coolant when the power unit stops operating.

In addition, the coolant preheating unit 20 is built into a preheating device capable of preheating the coolant, as shown, and is connected to preheat the coolant so that it flows to the power unit 10 through the principle of natural circulation.

The power generation unit 30 may be provided to generate and supply power by the power unit 10.

The power conversion unit 40 electrically connects the power unit 10 and the power generation unit 30 to convert the power from the power generation unit 30 into power for driving the power unit 10 and transmits it. It can be provided.

Figure 2 shows the overall configuration of the vibration reduction module 200 in a plan view of the case 100 of the coolant preheating device of the power generation unit 30 according to the present invention.

Referring to FIG. 2 , the coolant preheating device of the power generation unit 30 may include a case 100 and a vibration reduction module 200.

Case 100 protects the power unit 10, coolant preheating unit 20, power generation unit 30, and power conversion unit 40 by mounting them inside, and has a cover unit 110 so that the upper part can be opened. may be provided.

The vibration reduction module 200 may be installed along the inner circumference of the case 100 to prevent vibration and noise generated during operation of the power unit from being emitted to the outside.

In addition, the vibration reduction module 200 includes a machining spring 210, a module housing 220, a fixing part 230, a support plate 240, a support part 250, a fixing plate 260, a reduction part 270, And it may include a reduction part fixing member 280.

A plurality of machining springs 210 may be installed at each corner inside the case 100 to support the overall structure of the vibration reduction module 200.

A plurality of module housings 220 may be installed on each side of the case 100 and supported by a plurality of machining springs 210 .

A plurality of fixing parts 230 may be formed on one side and the other side of each of the plurality of module housings 220, spaced apart from each other at a certain distance.

A plurality of support plates 240 may be formed on one side of the plurality of fixing parts 230 along the longitudinal direction of the module housing 220.

A plurality of support portions 250 may be installed at regular intervals to support the plurality of support plates 240 .

A plurality of fixing plates 260 may be installed on one support plate 240 among the plurality of support plates 240 .

Figures 3 and 4 show the reduction unit 270 of the coolant preheating device of the power generation unit 30 according to the present invention.

Referring to FIGS. 3 and 4 , a plurality of reduction units 270 are formed at regular intervals in one direction of each of the plurality of fixing plates 260 and may be provided to attenuate the impact transmitted to the case 100. .

In addition, the reduction unit 270 includes a reduction unit body 271, a fitting member 272, a sensor bracket 273, a sensor protection member 274, a vibration measurement unit 275, a vibration spring 276, and a buffer unit ( 277), and may include a fastening portion 278.

*The reduction unit body 271 is provided in a cylindrical shape and a screw thread (E) may be formed at the rear end.

The fitting member 272 may be fastened along the thread E of the reduction unit body 271, and an insertion member 2721 may be formed in the central portion.

The sensor bracket 273 may be installed on the front end of the reduction unit body 271.

The sensor protection member 274 has a built-in vibration sensor 2741 that measures vibration caused by external impact, is provided with a plurality of sensor fixing rings 2742 for fixing the vibration sensor 2741, and has a sensor bracket 273. ) and may be formed to protrude from the front end of the reduction unit body 271.

The vibration measuring unit 275 may be installed on one side of the reduction unit body 271 and may be provided to calculate and display the average value of vibration measured by the vibration sensor 2741.

At this time, the unit of measurement is preferably N (Newton), which measures force.

Additionally, the vibration measuring unit 275 may be provided with a small display built into one side of the reduction unit body 271.

The vibration spring 276 can be inserted into the insertion member 2721 of the fitting member 272 to reduce external shock.

The buffer unit 277 is built inside the reduction unit body 271, and an insertion protrusion 2771 is formed on the rear end to be inserted into the front end of the vibration spring 276, and a spring for reducing vibration may be built in. .

The fastening part 278 includes a fastening screw 2781 at the upper end of the buffer part 277, a buffer spring 2782 inserted into the fastening screw 2781, and a separation prevention to prevent the shock absorber from being separated from the reduction part body 271. It can be fastened in the ring 2783 order.

The reduction part fixing member 280 may be installed on one side of the corresponding support plate 240 to be fastened to and fixed to at least one reduction part 270 among the plurality of reduction parts 270.

The assembly relationship and effect of the embodiment according to the above configurations are described in detail as follows.

The vibration reduction module 200 is installed along the inner circumference of the case 100.

A plurality of machining springs 210 are installed at each corner inside the case 100, and a module housing 220 is installed at each side inside the case 100.

The machining spring 210 is assembled to support the module housing 220.

Inside the module housing 220, a plurality of fixing parts 230 are formed to protrude on one side and the other side, and a support plate 240 is assembled to one side of the fixing part 230.

A plurality of support parts 250 are assembled at regular intervals to support the support plates 240 that face each other.

Meanwhile, a fixing plate 260 is formed on one of the plurality of support plates 240 and spaced apart from each other at a predetermined interval.

A plurality of reduction units 270 are formed at regular intervals in one direction of the fixing plate 260.

In particular, the reduction unit 270 is formed by a sensor protection member 274 with a built-in vibration sensor 2741 protruding from the front end of the reduction unit body 271, and has a fastening screw 2781 and a buffer inside the reduction unit body 271. A fastening part 278 and a buffer part 277 are connected in that order to a spring 2782 and a separation prevention ring 2783, and one end of the vibration spring 276 is attached to the insertion protrusion 2771 of the buffer part 277. It is inserted, and the insertion member 2721 of the fitting member 272 is inserted into the other end to assemble the thread E of the reduction part body 271 and the fitting member 272.

The reduction part fixing member 280 is installed and assembled on one side of the support plate 240 at a corresponding position so that it is fastened and fixed to the reduction part 270.

The vibration reduction module 200 is supported inside the case 100 by the machining spring 210, and when an external shock is transmitted to the case 100, the vibration spring 276 and the shock absorber 277 among the reduction parts 270 There is an effect of reducing external shock and preventing shock from being transmitted to the power unit 10, the coolant preheating unit 20, the power conversion unit 40, and the power generation unit 30.

In addition, the vibration reduction module 200 measures external shock at the vibration sensor 2741 of the reduction unit 270, calculates the average value of the vibration, and displays it on the vibration measurement unit 275 so that the administrator can periodically use the terminal to reduce the vibration effect. It is possible to check whether the and reduction unit 270 is broken.

Figure 5 shows an embodiment of the dust removal module 300 of the coolant preheating device of the power generation unit 30 according to the present invention.

Referring to FIG. 5 , the coolant preheating device of the power generation unit 30 may further include a dust removal module 300.

The dust removal module 300 is installed inside the bottom of the case 100 to remove dust introduced into the case 100 or harmful gases generated during operation of the power unit and heat from the power unit 10 and the coolant preheating unit 20. can be released to the outside.

Additionally, the dust removal module 300 may include an air tank 310, an injection unit 320, and a pipe 330.

The air tank 310 may be installed inside the case 100 to store compressed air, and may be equipped with a built-in pump that operates under the control of an electrically connected control unit to supply the compressed air.

Figures 6 and 8 show the injection unit 320 of the coolant preheating device of the power generation unit 30 according to the present invention.

Referring to FIGS. 6 and 8 , a plurality of spray units 320 are inserted into the lower surface of the case 100 at regular intervals, and may be provided to spray compressed air into the case 100.

Additionally, the injection unit 320 may include a pipe protection member 321, a screw injection unit 322, an injection unit fastening unit 323, and an injection unit fixing member 324.

The pipe protection member 321 has a built-in pipe 330 and is formed in the center with a spray groove 3211 through which compressed air supplied from the pipe 330 is sprayed and a plurality of bolt holes D into which bolts can be inserted along the circumference. It can be.

Figure 7 shows the overall configuration of the screw injection unit 322 of the coolant preheating device of the power generation unit 30 according to the present invention.

Referring to FIG. 7, the screw injection unit 322 has a fitting member 3221 protruding on one side to be fastened to the injection groove 3211 of the pipe protection member 321, and the compression sprayed from the injection groove 3211 is formed. Air can be supplied by adding rotational force.

In addition, the screw injection unit 322 is electrically connected to the cylindrical nozzle body 322A and the control unit and is built into the nozzle body 322A for rotational operation, and a screw fastening part 322B-1 is formed along the circumference. It may include a screw body 322B.

At this time, the screw fastening part 322B-1 may be fastened to the dust removal part 322B-2, which removes dust flowing into the screw spraying part 322.

Additionally, the screw injection unit 322 may include an auxiliary injection unit 322C that is integrally connected to one end of the screw body 322B and selectively sprays compressed air under the control of a control unit.

The auxiliary injection unit 322C may include a connection portion 322C-1 integrally connected to one end of the screw body 322B.

Additionally, the auxiliary injection unit 322C may include an auxiliary injection nozzle 322C-2 that is integrally connected to the connection unit 322C-1 and selectively sprays compressed air.

The injection part fastening part 323 is formed by a body fixing member 3231 with a central part protruding so that the screw injection part 322 can be inserted, and a plurality of inclined grooves and bolt holes (C) are spaced at regular intervals along the inner circumference. can be formed.

*The injection unit fixing member 324 is engaged with a plurality of fitting grooves 3232 of the injection unit fastening unit 323, has a central portion that is perforated to be inserted into the body fixing member 3231, and is spaced at regular intervals along the circumference with a plurality of bolts. A hole B is formed, and a berm portion 3241 in which a plurality of bolt holes A are formed may be provided to protrude so as to be bolted to the case 100 on the upper surface.

The effects of different assembly relationships and embodiments of the above configurations are described in detail as follows.

The dust removal module 300 is installed inside the case 100 along the bottom surface.

The air tank 310 is installed inside the case 100 and connected to the spray unit 320 through the pipe 330.

In particular, the injection unit 320 is provided with a pipe protection member 321 at the bottom to connect and protect the pipe 330.

The injection unit 320 includes a pipe protection member 321 to which the pipe 330 is connected, a screw injection unit 322 assembled in the injection groove 3211 of the pipe protection member 321, and a screw injection unit 322 at the center. The assembled injection unit fastening part 323 and the injection unit fixing member 324 inserted by the body fixing member 3231 are sequentially assembled with bolts in the bolt holes (B to D) and are integrally fastened.

In addition, the spray unit fixing member 324 is bolted to the case 100 through the bolt hole A and is assembled to fix the spray unit 320.

Meanwhile, a screw fastening part 322B-1 is formed inside the nozzle body 322A of the screw injection part 322 so that the dust removal part 322B-2 is fastened to the peripheral part, and the front end of the screw body 322B A screw body 322B on which an auxiliary injection portion 322C is formed is built.

The dust removal module 300 sprays compressed air supplied from the air tank 310 through a plurality of pipes 330 into the case 100 through a plurality of injection units 320 under the control of the control unit, thereby spraying the case ( 100) It is effective in removing dust that flows inside or accumulates on the power unit 10, the coolant preheating unit 20, the power generation unit 30, and the power conversion unit.

In particular, the dust removal module 300 rotates the screw body 322B under the control of the control unit to remove dust introduced into the screw injection unit 322 through the dust removal unit 322B-2, and the screw body 322B ) Due to the rotation of the compressed air supplied through the pipe 330, rotational force is added and the compressed air is sprayed in rotation, which has the effect of spraying the compressed air evenly into the case 100.

In addition, the dust removal module 300 selectively opens the auxiliary injection nozzle 322C-2 of the auxiliary injection unit 322C under the control of the control unit to increase the amount of dust or compress it to form a circulating airflow inside the case 100. The screw injection unit 322 can be assisted by spraying air.

Although preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and may be used in the technical field to which the invention pertains without departing from the gist of the invention as claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or perspective of the present invention.

Power unit (10)
Coolant preheating unit (20)
Power generation unit (30)
Power conversion unit (40)
Case(100)
Cover part (110)
Vibration reduction module (200)
Machining spring (210)
Module housing(220)
Fixing part (230)
Support plate (240)
Support part (250)
Fixing plate (260)
Reduction unit (270)
Reduction body (271)
thread (E)
Fitting member (272)
Insertion member (2721)
Sensor bracket (273)
Sensor protection member (274)
Vibration Sensor(2741)
Sensor fixing ring (2742)
Vibration measurement unit (275)
Oscillating Spring(276)
Buffer section (277)
Insertion protrusion (2771)
Fastener (278)
Clamping screw (2781)
Shock spring (2782)
Anti-removal ring (2783)
Reduction part fixing member (280)
Dust removal module (300)
Air Tank(310)
Injection unit (320)
Pipe protection member (321)
Spray groove (3211)
Bolt Ball (D)
Screw injection unit (322)
Nozzle body (322A)
Screw body (322B)
Screw fastener (322B-1)
Dust removal unit (322B-2)
Auxiliary injection unit (322C)
Connection (322C-1)
Auxiliary injection nozzle (322C-2)
Fitting member (3221)
Injection part fastening part (323)
Body fixing member (3231)
Fitting groove (3232)
Bolt Ball (C)
Injection part fixing member (324)
Bolt ball (B)
Bolt ball (A)
Berm (3241)
Pipe(330)

Claims (2)

A power unit that generates rotational force;
In the automobile coolant preheating device comprising,
a coolant preheating unit connected to the power unit to increase lubricity of the power unit by preheating the coolant when the power unit stops operating;
Including,
A case that protects the power unit and the coolant preheating unit by mounting them therein, and has a cover so that the top can be opened;
A vibration reduction module installed along the periphery of the inside of the case to prevent vibration and noise generated during operation of the power unit from being emitted to the outside;
A dust removal module installed inside the bottom of the case to discharge dust introduced into the case, harmful gases generated when the power unit operates, and heat from the power unit and the coolant preheating unit to the outside;
Including,
The vibration reduction module,
a plurality of machining springs installed at each corner inside the case to support the vibration reduction module;
a plurality of module housings installed on each side of the case and supported by the plurality of machining springs;
a plurality of fixing parts formed at regular intervals on one side and the other inside each of the plurality of module housings;
a plurality of support plates formed along the longitudinal direction of the module housing on one side of the plurality of fixing parts;
A plurality of support parts installed at regular intervals to support between the plurality of support plates;
A plurality of fixing plates installed on one of the plurality of support plates;
A plurality of reduction units are formed at regular intervals in one direction of each of the plurality of fixing plates to attenuate an impact transmitted to the case;
a reduction unit fixing member installed on one side of the corresponding support plate to be fastened to and fixed to at least one of the plurality of reduction units;
Including,
The reduction unit,
A reduction body provided in a cylindrical shape and having a thread (E) formed at the rear end;
A fitting member (272) fastened along the thread (E) of the reduction unit body and having an insertion member formed in the central portion;
A sensor bracket installed on the front end of the reduction unit body;
A sensor is provided with a built-in vibration sensor that measures vibration caused by an external impact, is provided with a plurality of sensor fixing rings for fixing the vibration sensor, is fixed by the sensor bracket, and is formed to protrude from the front end of the reduction unit body. protective member;
a vibration measuring unit installed on one side of the reduction unit body to calculate and display an average value of vibration measured by the vibration sensor;
a vibration spring inserted into the insertion member of the fitting member 272 to reduce external shock;
A buffer unit built inside the reduction unit body, has an insertion protrusion formed at the rear end to be inserted into the front end of the vibration spring, and has a built-in spring for reducing vibration;
A fastening part fastened to the upper end of the buffer in the following order: a fastening screw, a buffer spring inserted into the fastening screw, and a separation prevention ring for preventing separation of the buffer from the reduction unit body;
Including,
The vibration reduction module,
Supported inside the case by the machining spring,
When an external shock is transmitted to the case, the external shock is reduced in the vibration spring and the buffer part among the reduction parts,
It further includes a feature of measuring an external shock by the vibration sensor, calculating an average value of vibration, and displaying the average value of the vibration on the vibration measuring unit,
The dust removal module,
an air tank installed inside the case to store compressed air and to supply compressed air with a built-in pump operating under the control of an electrically connected control unit;
A plurality of spray units are inserted at regular intervals on the bottom surface of the case and spray compressed air into the case;
a pipe that is integrally connected to each of the plurality of spraying units and moves the compressed air sprayed from the air tank;
Including,
The injection unit,
A pipe protection member containing the pipe and having a spray groove in the center through which compressed air supplied from the pipe is sprayed and a plurality of bolt holes D into which bolts can be inserted along the periphery.
A screw injection unit having a fitting member 3221 protruding from one side to be fastened to the injection groove of the pipe protection member and supplying compressed air sprayed from the injection groove by adding rotational force;
A body fixing member with a central portion protruding so that the screw injection portion is inserted is formed, and a plurality of injection portion fastening portions are formed with fitting grooves and bolt holes (C) spaced apart from each other at regular intervals along the inner circumference portion.
The injection unit fastening part is engaged with the plurality of fitting grooves and is perforated in the central part to be inserted into the body fixing member, and a plurality of bolt holes B are formed at regular intervals along the circumference, and are bolted to the case on the upper surface. A spray unit fixing member having a protruding berm on which a plurality of bolt holes (A) are formed;
Including,
The screw injection unit,
A cylindrical nozzle body;
a screw body electrically connected to the control unit and built into the nozzle body for rotational operation, and having a screw fastening portion formed along a peripheral portion;
an auxiliary injection unit integrally connected to one end of the screw body and selectively spraying compressed air under the control of the control unit;
Including,
The auxiliary injection unit,
a connection portion integrally connected to one end of the screw body;
an auxiliary injection nozzle that is integrally connected to the connection portion and selectively sprays compressed air;
Including,
The screw fastening part,
A dust removal unit is fastened to remove dust flowing into the screw injection unit,
The dust removal module,
Under the control of the control unit, the compressed air supplied from the air tank is injected into the case through the plurality of pipes and the plurality of injection units,
Under the control of the control unit, the screw body rotates to remove dust introduced into the screw injection unit to the dust removal unit, and the compressed air supplied through the pipe due to rotation is rotated and sprayed by adding rotational force,
The automobile coolant preheating device further includes a feature in which the auxiliary injection nozzle of the auxiliary injection unit is opened under control of the control unit to spray compressed air. delete